CHCNAV iBase

 The iBase GNSS station is an all-in-one RTK GNSS station. No more cables or external batteries. No need to take many accessories, resulting in easier operation. The simplicity of the setup process improves work efficiency at least 3 times compared to conventional external radio solutions. Beyond a simple GNSS station, the iBase also includes a 4G modem for transmitting GNSS corrections via TCP/IP server. 

 The iBase GNSS electronics design significantly reduces power needs without sacrificing the UHF modem's performance. Its two high-capacity removable batteries provide up to 12 hours of continuous operation when transmitting RTK corrections at 5 watts power output. The iBase can also be connected to 240v mains power for continuous operation. With the UHF it can cover up to 25 km in optimal conditions and up to 5km under challenging conditions such as wooded and suburban areas. 

 The state-of-the-art 1408-channel GNSS technology leverages GPS, GLONASS, Galileo and BeiDou. The iBase GNSS integrates cutting-edge GNSS antenna technology and multipath mitigation algorithms to ensure that the highest quality GNSS corrections are transmitted to the GNSS rovers. 

 iBase is the GNSS base receiver that you can rely on regardless of your working environment. Its industrial design meets the stringent IP67 standard for water and dust ingress protection. The IK08 impact protection level further extends the life of the iBase GNSS receiver, allowing it to withstand accidental falls from the height of a tripod onto hard ground. 

 The iBase GNSS receiver is a fully integrated professional GNSS base station specifically designed to meet 95% of surveyors' needs when working in UHF GNSS base and rover mode. The performance of the iBase UHF base station compared to a standard external UHF radio modem is almost perfect. But its unique design eliminates the need for a heavy external battery, cumbersome cables, external radio, and radio antenna. Its 5-watt radio module provides operational GNSS RTK coverage up to 25 km in optimal conditions, and a real-time UHF interference self-checking technique allows the operator to select the most appropriate frequency channel to use.